DE2718896C3 - Achromatic microscope objective consisting of three lens elements - Google Patents

Description

lead to objectives with the same numerical aperture AfA and the same magnification β , where n _{d is} the refractive index at the wavelength 587.6 nm and v _d is the Abbe number.

3. Achromatic microscope objective with a magnification in the range of 35 to 45 times and a numerical aperture > 0.60, consisting of three lens elements, the first lens element being a single converging lens and the third lens element being a cemented element made of a diverging and a biconvex converging lens, characterized in that the second lens element (3) is designed as a single converging lens, that the lenses are made of inexpensive bulk glasses excluding lanthanum glasses and that the values given in the following data table for surface curvature r, distance and thickness d, refractive index n _d and the Abbe number v _d

lens

radius 1,149 thickness &tgr; d Γ, =- 0.646 8,017 d ₂ = QMl ^r i —— _r3 = 1,385 4,951 _d4 = 0.524 _r4 = - 's = 1.116 _d6 = 0.244 '6 = 2,164 _d7 = 0.768 &rgr; ₌

Distance d

Refractive index

Abbe number

_dx = 0.134

_d3 = 0.097

_ds = 0.700

1.60738
1.62041

1.78470
1.51112

56.65
60.33

26.08
60.41

/ == 1, &bgr; - 45 x, NA = 0.65

are complied with or values obtained by varying this data set when selecting the glass data for the lens elements in the ranges given below:

first lens element (2)

second lens element (3)

diverging lens (4) of the third lens element biconvex converging lens (S) of the ¹ ? third lens element

n _d > 1.55,66 > v _d > 45
n _d > 1.55,66 > v _d > 45
n _d > 1.65. V ₁ , > 40
n _d < 1.57,72 > v _d > 50

to objectives with the same numerical aperture NA and the same magnification β , where n _{d is} the refractive index at the wavelength 587.6 nm and v _d is the Abbe number.

The present invention relates to an achromatic microscope objective with a magnification in the range of 35 to 45 times and a numerical aperture > 0.60, consisting of three lens elements, the first lens element being a collecting single lens and the third lens element being a cemented element made of a diverging and a biconvex collecting lens.

DE-PS 24 24 399 discloses a microscope objective with 40x magnification and a numerical aperture of 0.65, which consists of three lens elements with a total of five lenses. The first lens element is a single converging lens, the second and third lens elements are each formed as a cemented element made of a negative and a biconvex converging lens. In this conventional objective, the refractive power required for the real image is distributed over three converging lenses. Two diverging lenses are provided to compensate for the spherical aberration and negative chromatic longitudinal aberration generated by these.

This well-known lens is relatively expensive due to the use of a total of five lenses and also requires a relatively high level of manufacturing effort to produce the two cemented elements.

There has been no lack of attempts to construct achromatic microscope objectives, i.e. inexpensive objectives with achromatic correction, from as few lenses as possible. This has also been achieved for microscope objectives with low magnification and small aperture; however, attempts to develop such objectives with high magnification and high aperture have not been successful.

DE-OS 25 Oft 957 discloses a microscope objective with 25x magnification and an aperture of 0.40, which consists of a total of 4 lenses. The first two lenses are individual collecting lenses, followed by a cemented element consisting of a diverging and a collecting lens. The advantage of a structure with only 4 lenses achieved with this objective with a low magnification and a relatively low aperture cannot simply be transferred to a microscope objective with a high magnification and at the same time a high aperture, the focal length of which is naturally much shorter. A proportional calculation does not lead to success. The object of the present invention is to create an inexpensive achromatic microscope objective with a magnification ⁱⁿ the range of 35 to 45 times and a numerical aperture > 0.60, which consists of only 4 lenses and whose imaging performance is at least comparable to that of known objectives. m This means that this lens should be constructed exclusively using inexpensive mass-produced glasses for reasons of low cost and the manufacturing effort should be kept as low as possible. This task is solved by the features listed in the characterizing part of the independent claims 1, 2 and 3. The claimed combination of features meets the requirement for the use of inexpensive, tropicalized mass-produced glasses; the radii and distances between the lens elements inevitably result from the usual correction requirements for an achromatic lens with this choice of glass.

In the lens according to the invention, contrary to the known construction principle according to which the

In order to keep the refractive index η as low as possible in negative lenses, a high-refractive index glass with high color fidelity should be chosen in order to have a positive effect on the Petzval sum. By choosing such a glass for the negative lens, it is possible to compensate for the longitudinal chromatic aberration of the other lenses of this lens, which are designed as convex lenses.

The glass used for the negative lens can be a mass-produced glass with a refractive index n,, > 1 f>5 and an Abbe number v _d < 40. Such a glass is available, for example, under the designation SF 56.

The first two lens elements are designed to minimize color dispersion

and at the same time have a positive influence on the Pctzval sum. This can be achieved by using bulk glasses that have a high Abbe number and a high refractive index. Glasses from the range n _d > 1.55 with v _d 45 are suitable, for example glasses that are available under the designation SK 2, SK 16 or SK 51.

The high aperture of > 0.60 of the objective according to the invention means that the fourth lens, designed as a converging lens, has such a low refractive index that a high refractive index difference occurs at its interface (cemented surface) with the negative lens. This makes it possible to keep the spherical center error small despite the high aperture. The Abbe number is chosen so that, in conjunction with the other lens elements, the longitudinal chromatic deviation is well corrected. A mass-produced glass from the range n _d < 1.57 with ν > 50 is suitable, as is available, for example, under the designation K 7.

Despite the unfavorable influence of the cemented element on the Petzval sum, the glass selection described makes it possible to achieve an image field flattening that is even better than that of known 5-lens microscope lenses.

In order to be able to use the lens according to the invention together with other lenses of the applicant in which the chromatic magnification difference is 1.35 to 1.5%, it is advantageous to choose the air distance rf ₅ between the second single lens and the third lens element so that d<, = 0.8 /-". F w is the focal length of the lens.

It is of course also possible to choose a different size d ₅ in order to obtain a different desired chromatic magnification difference.

An embodiment of a microscope objective according to the invention is specified in claim 3.
The invention will now be explained in more detail with reference to Fig. 1-4 of the drawings and the following tables. In detail,

Fig. 1 an embodiment of the new microscope objective with a 40x magnification and a numerical aperture of 0.65,

Fig. 2 the curves for the spherical aberration of the lens according to Fig. 1,
Fig. 3 the curves for the astigmatism of the lens according to Fig. 1,
Fig. 4 shows the distortion curve of the lens according to Fig. 1.

In Fig. 1, 1 denotes a cover glass of the usual thickness of 0.17 mm. The first lens 2 of the objective is

a concave-convex converging lens, followed by the second single lens 3, designed as a biconvex converging lens. The third lens element is designed as a cemented element and consists of a negative lens 4 and a biconvex positive lens 5. To illustrate the beam path, the main ray 6 and the central bundle delimited by the rays 7 and 8 are shown.

The following data table lists the values for the radii r, the thicknesses and distances d as well as the refractive index n _d and the Abbe number v _d of the glasses used for the microscope objective shown in Fig. 1.

Table I

/= 1, &bgr; -40 κ, NA = 0.65

lens Radius> 1,089 thickness Absland Refractive index Abbe number &Ggr; '' «,&igr; 0.640 i/, = 1 r, = - 7,938 r, = 0.624 1.60738 56.65 /■·. = &mdash; 1,371 f/, = II /·, = 4,902 r/ ₄ = 0.520 1.62041 60.33 r, = - 1.105 d-, ■ III r, = 2.143 d&rdquor; = 0.217 1.78470 26.08 r _h - _d7 = 0.761 1.51112 60.41 ri = &mdash; = 0.130 = 0.098 = 0.704

As Fig. 2 shows, the spherical aberration of this lens is well corrected, as is the astigmatism, as shown in Fig. 3. The curvature between curves s and m in Fig. 3 is improved by 30% in the new microscope lens compared to comparable lenses with five lenses. As Fig. 4 shows, the lens according to Table 1 has only a very small distortion.

Figures 2 to 4 generally show that, despite the use of only four lenses, the center correction and distortion of the objective shown are at least equivalent to comparable objectives with five lenses, but that the mean curvature is significantly improved. The following tables show the data for two further embodiments of the microscope objective according to the invention.

Table II

/= 1.0-35 &kgr;, NA = 0.65

lens radius 1,058 thickness Distance Refractive index Abbe number &Ggr; "ll 0.639 I r, = - 7,935 _d2 = 0.623 1.60738 56.65 r. = - 1,371 ^ ₃ = II r, = 4,904 </&ldquor; = 0.519 1.62041 60.33 _r4 = - 1,092 III ^{r5 =} 2,142 d _b = 0.192 1.78470 26.08 r _k = _d7 = 0.760 1.51112 60.41 r- = - = 0.140 = 0.098 = 0.690

Table III

/= &igr;, &bgr; - 45 κ, NA = 0.65

lens radius 1,149 thickness Distance Refractive index Abbe number r d V,&igr; 0.646 r, = 0.134 1 η = - 8,017 _dz =0.622 1.60738 56.65 r-, = - 1,385 d, = 0.097 II f\ - 4,951 f/ ₄ = 0.524 1.62041 60.33 _r4 = - 1.116 i/, = 0.700 III _r , = 2,164 // _;i = n.244 1.78470 26.08 '<, = r ₇ = 0.768 1.51112 60.41 _r7 = - For this 2 Sheet Drawings

Claims (1)

Patent claims: 1. Achromatic microscope objective with a magnification in the range of 35 to 45 times and a numerical aperture > 0.60, consisting of three lens elements, the first lens element being a single converging lens and the third lens element being a cemented element made of a diverging and a biconvex converging lens, characterized in that the second lens element (3) is designed as a single converging lens, that the lenses are made of inexpensive bulk glasses excluding lanthanum glasses and that the values given in the following data table for surface curvature r, distance and thickness d. Refractive index n _d and the Abbe number v _d lens radius 1,089 thickness Distance Refractive index Abbe number &Ggr; d d Vd 0.640 A _x - I Γ, = - 7,938 _d2 = 0.624 1.60738 56.65 _T2 =- 1,371 d ₃ ·■ The - ^r 3 &mdash; 4,902 _dA = 0.520 1.62041 60.35 _r4 = - 1.105 ds- III ^r5 = 2.143 d _b = 0.217 1.78470 26.08 _r6 = d-, = 0.761 1.51112 60.41 Γ-7 = &mdash; = 0.130 = 0.098 = 0.704 /= l,ß- 40x, NA =0.65 are complied with by varying this data set when selecting the glass data for the lens elements in the ranges given below: first lens element (2) second lens element (3) diverging lens (4) of the third lens element biconvex collecting lens (5) of the third lens element n _d > 1.55.66> tij> 1.55.66 > n _rf >1.65, v _rf >40 /i _rf <1.57.72>Vj>50 to objectives with the same numerical aperture NA and the same magnification β , where n _{d is} the refractive index at the wavelength 587.6 nm and v _d is the Abbe number. 2. Achromatic microscope objective with a magnification in the range of 35 to 45 times and a numerical aperture > 0.60, consisting of three lens elements, the first lens element being a single converging lens and the third lens element being a cemented element made of a diverging and a biconvex converging lens, characterized in that the second lens element (3) is designed as a single converging lens, that the lenses are made of inexpensive bulk glasses excluding lanthanum glasses and that the values given in the following data table for surface curvature r, distance and thickness d, refractive index n _d and the Abbe number v _d lens radius thickness Distance Refractive index Ablic number I r, = - 1.058 d, = 0.623 _r2 = - 0.639 II r, = 7.935 r ₄ = 0.519 O = - 1.371 III _r5 = 4.904 4 = 0.192 /■&rdquor; = 1.092 ₍ /. = 0.760 _r7 = - 2.142 f = 1.0- 35 x. ;V/\ = 0.65 d, = 0.140 = 0.098 i/s = 0.690 1.60738
1.62041 1.78470
1.51112 56.65 60.33 26.08 60.41 are complied with or values obtained by varying this data set when selecting the glass data for the lens elements in the ranges given below: first lens element (2) second lens element (3) diverging lens (4) of the third lens element biconvex collecting lens (S) of the third lens element n _d > 1.55,66 > v _d > 45
n _d > 1.55,66 > v _d > 45
n _d > 1.65, v _d > 40
n _d < 1.57, 72>v _d > 50